ADN2807ACP_技术文档

155/622 Mb/s Clock and Data Recovery IC

with Integrated Limiting Amp

ADN2807

GENERAL DESCRIPTION

FEATURES

Meets SONET requirements for jitter transfer/

generation/tolerance

Quantizer sensitivity: 4 mV typical

Adjustable slice level: 100 mV

Patented clock recovery architecture

Loss-of-signal detect range: 3 mV to 15 mV

Single-reference clock frequency for all rates, including

15/14 (7%) wrapper rate

Choice of 19.44 MHz, 38.88 MHz, 77.76 MHz, or

155.52 MHz REFCLK

REFCLK inputs: LVPECL/LVDS/LVCMOS/LVTTL compatible

(LVPECL/LVDS only at 155.52 MHz)

Optional 19.44 MHz on-chip oscillator to be used with

external crystal

Loss-of-lock indicator

The ADN2807 provides the receiver functions of quantization,

signal level detect, and clock and data recovery at rates of OC-3,

OC-12, and 15/14 FEC. All SONET jitter requirements are met,

including jitter transfer, jitter generation, and jitter tolerance. All

specifications are quoted for –40°C to +85°C ambient

temperature, unless otherwise noted.

The device is intended for WDM system applications and can

be used with either an external reference clock or an on-chip

oscillator with external crystal. Both native rates and 15/14 rate

digital wrappers are supported by the ADN2807, without any

change of reference clock.

This device, together with a PIN diode and a TIA preamplifier,

can implement a highly integrated, low cost, low power, fiber

optic receiver.

Loopback mode for high speed test data

Output squelch and bypass features

Single-supply operation: 3.3 V

Low power: 540 mW typical

The receiver front end signal detect circuit indicates when the

input signal level has fallen below a user adjustable threshold.

The signal detect circuit has hysteresis to prevent chatter at the

output.

7 mm × 7 mm, 48-lead LFCSP

APPLICATIONS

SONET OC-3/-12, SDH STM-1/-4 and, 15/14 FEC rates

WDM transponders

The ADN2807 is available in a compact 7 mm × 7 mm 48-lead

chip-scale package (LFCSP).

Regenerators/repeaters

Test equipment

Passive optical networks

FUNCTIONAL BLOCK DIAGRAM

SLICEP/N

2

VCC

VEE

LOL

CF1

CF2

ADN2807

LOOP

FILTER

2

REFSEL[0..1]

NIN

2

REFCLKP/N

XO1

/n

FREQUENCY

LOCK

DETECTOR

PHASE

SHIFTER

LOOP

FILTER

PHASE

DET.

QUANTIZER

VCO

XTAL

OSC

XO2

FRACTIONAL

DIVIDER

VREF

REFSEL

LEVEL

DATA

DIVIDER

DETECT

RETIMING

1/2/4/16

3

2

THRADJ

SDOUT

DATAOUTP/N

CLKOUTP/N

SEL[0..2]

Figure 1.

Rev. A

Information furnished by Analog Devices is believed to be accurate and reliable.

However, no responsibility is assumed by Analog Devices for its use, nor for any

infringements of patents or other rights of third parties that may result from its use.

Specifications subject to change without notice. No license is granted by implication

or otherwise under any patent or patent rights of Analog Devices. Trademarks and

registered trademarks are the property of their respective owners.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.

Tel: 781.329.4700

Fax: 781.326.8703

www.analog.com

ADN2807

TABLE OF CONTENTS

Specifications..................................................................................... 3

Absolute Maximum Ratings............................................................ 5

Thermal Characteristics .............................................................. 5

ESD Caution.................................................................................. 5

Pin Configuration and Function Descriptions............................. 6

Definition of Terms.......................................................................... 8

Maximum, Minimum, and Typical Specifications................... 8

Input Sensitivity and Input Overdrive....................................... 8

Single-Ended vs. Differential ...................................................... 8

LOS Response Time ..................................................................... 9

Jitter Specifications....................................................................... 9

Theory of Operation ...................................................................... 10

Functional Description .................................................................. 12

Multirate Clock and Data Recovery......................................... 12

Limiting Amplifier ..................................................................... 12

Slice Adjust.................................................................................. 12

Loss-of-Signal (LOS) Detector ................................................. 12

Reference Clock.......................................................................... 12

Lock Detector Operation .......................................................... 13

Squelch Mode ............................................................................. 14

Test Modes—Bypass and Loop-back....................................... 14

Application Information................................................................ 15

PCB Design Guidelines ............................................................. 15

Choosing AC Coupling Capacitors.......................................... 17

DC-Coupled Application .......................................................... 17

LOL Toggling during Loss of Input Data................................ 17

Outline Dimensions....................................................................... 19

Ordering Guide .......................................................................... 19

REVISION HISTORY

5/04—Data Sheet Changed from Rev. 0 to Rev. A

Changes to Specifications............................................................ 3

Change to Table 7 and Table 8 .................................................. 13

1/04—Revision 0: Initial Version

Rev. A | Page 2 of 20

ADN2807

SPECIFICATIONS

Table 1. T_A= T_MINto T_MAX, VCC = V_MINto V_MAX, VEE = 0 V, C_F= 4.7 µF, SLICEP = SLICEN = VCC, unless otherwise noted

Parameter

Conditions

Min

Typ

Max

Unit

QUANTIZER–DC CHARACTERISTICS

Input Voltage Range

Peak-to-Peak Differential Input

Input Common-Mode Level

Differential Input Sensitivity

Input Overdrive

@ PIN or NIN, dc-coupled

0

1.2

2.4

V

DC-coupled (See Figure 26)

PIN−NIN, ac-coupled¹, BER = 1 × 10^–10

See Figure 8

0.4

4

2

500

244

10

5

mV p-p

µV

Input Offset

Input RMS Noise

BER = 1 × 10^–10

µV rms

QUANTIZER–AC CHARACTERISTICS

Small Signal Gain

Input Resistance

Differential

54

dB

Ω

pF

ps

100

0.65

10

Input Capacitance

Pulse-Width Distortion²

QUANTIZER SLICE ADJUSTMENT

Gain

SliceP – SliceN = 0.5 V

SliceP – SliceN

@ SliceP or SliceN

0.11

–0.8

1.3

0.20

1.0

0.30

+0.8

VCC

V/V

V

Control Voltage Range

Slice Threshold Offset

mV

LEVEL SIGNAL DETECT (SDOUT)

Level Detect Range (See Figure 4)

R_THRESH= 2 kΩ

9.4

2.5

0.7

0.1

13.3

5.3

3.0

18.0

7.6

5.2

5

mV

µs

R

_THRESH= 20 kΩ

_THRESH= 90 kΩ

Response Time

DC-coupled

0.3

Hysteresis (Electrical)

OC-12, PRBS 2²³

R

_THRESH= 2 kΩ

_THRESH= 20 kΩ

_THRESH= 90 kΩ

_THRESH= 90 kΩ @ 25°C

OC-3, PRBS 2²³

_THRESH= 2 kΩ

_THRESH= 20 kΩ

_THRESH= 90 kΩ

_THRESH= 90 k @ 25°C

4.7

1.8

6.4

6.0

6.3

6.9

7.8

10.0

dB

4.8

3.6

8.9

8.5

R

6.2

5.6

6.6

dB

3.4

9.9

OC-12, PRBS 2⁷

R

_THRESH= 2 kΩ

_THRESH= 20 kΩ

_THRESH= 90 kΩ

5.7

3.9

3.2

6.6

6.2

6.7

7.8

8.5

9.9

dB

OC-3, PRBS 2⁷

R

_THRESH= 2 kΩ

_THRESH= 20 kΩ

5.4

4.6

3.9

6.6

6.4

6.8

7.7

8.2

9.7

dB

R_THRESH= 90 kΩ

LOSS-OF-LOCK DETECTOR (LOL)

Loss-of-Lock Response Time

POWER SUPPLY VOLTAGE

POWER SUPPLY CURRENT

From f_VCOerror > 1000 ppm

60

mV

V

3.0

3.3

164

3.6

150

215

mA

Rev. A | Page 3 of 20

ADN2807

Parameter

Conditions

PIN–NIN = 10 mV p-p

OC-12

Min

Typ

Max

Unit

PHASE-LOCKED LOOP CHARACTERISTICS

Jitter Transfer BW

140

48

200

85

kHz

OC-3

Jitter Peaking

OC-12

OC-3

0.004

0.002

dB

Jitter Generation

OC-12, 12 kHz to 5 MHz

0.003

0.04

0.002

0.04

UI rms

UI p-p

UI rms

UI p-p

0.02

OC-3, 12 kHz to 1.3 MHz

Jitter Tolerance

OC-12

30 Hz³

300 Hz

25 kHz

250 kHz³

OC-3

100

44

5.8

1.0

UI p-p

30 Hz³

300 Hz³

6500 Hz

65 kHz³

50

UI p-p

23.5

6.0

1.0

CML OUTPUTS (CLKOUTP/N, DATAOUTP/N)

Single-Ended Output Swing

Differential Output Swing

Output High Voltage

Output Low Voltage

Rise Time

V_SE(See Figure 7)

V_DIFF(See Figure 7)

V_OH

V_OL, referred to VCC

20% to 80%

80% to 20%

T_S(See Figure 3)

OC-12

400

850

488

975

VCC

540

1100

mV

V

ps

–0.60

–0.30

150

Fall Time

Setup Time

750

3145

ps

OC-3

Hold Time

T_H(See Figure 3)

OC-12

750

3150

ps

OC-3

REFCLK DC INPUT CHARACTERISTICS

Input Voltage Range

@ REFCLKP or REFCLKN

0

VCC

V

Peak-to-Peak Differential Input

Common-Mode Level

TEST DATA DC INPUT CHARACTERISTICS⁴

(TDINP/N)

Peak-to-Peak Differential Input Voltage

LVTTL DC INPUT CHARACTERISTICS

Input High Voltage

100

mV

V

DC-coupled, single-ended

CML inputs

VCC/2

0.8

V

V_IH

2.0

V

Input Low Voltage

Input Current

Input Current (SEL0 and SEL1 Only)⁵

LVTTL DC OUTPUT CHARACTERISTICS

Output High Voltage

V_IL

0.8

+5

+50

V

µA

V_IN= 0.4 V or V_IN= 2.4 V

–5

V_OH, I_OH= –2.0 mA

V_OL, I_OL= +2.0 mA

2.4

V

Output Low Voltage

0.4

¹PIN and NIN should be driven differentially, ac-coupled for optimum sensitivity.

²PWD measurement made on quantizer outputs in BYPASS mode.

³Jitter tolerance measurements are equipment limited.

⁴TDINP/N are CML inputs. If the drivers to the TDINP/N inputs are anything other than CML, they must be ac-coupled.

⁵SEL0 and SEL1 have internal pull-down resistors, causing higher I_IH.

Rev. A | Page 4 of 20

ADN2807

ABSOLUTE MAXIMUM RATINGS

Table 2.

THERMAL CHARACTERISTICS

Parameter

Rating

Thermal Resistance

Supply Voltage (VCC)

5.5 V

48-Lead LFCSP, 4-layer board with exposed paddle soldered

to VCC

Minimum Input Voltage (All Inputs)

Maximum Input Voltage (All Inputs)

Maximum Junction Temperature

Storage Temperature

VEE – 0.4 V

VCC + 0.4 V

165°C

θ_JA= 25°C/W

–65°C to +150°C

Lead Temperature (Soldering 10 sec) 300°C

Stresses above those listed under Absolute Maximum Ratings

may cause permanent damage to the device. This is a stress

rating only; functional operation of the device at these or any

other conditions above those indicated in the operational

section of this specification is not implied. Exposure to absolute

maximum rating conditions for extended periods may affect

device reliability.

ESD CAUTION

ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on

the human body and test equipment and can discharge without detection. Although this product features

proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy

electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance

degradation or loss of functionality.

Rev. A | Page 5 of 20

ADN2807

PIN CONFIGURATION AND FUNCTION DESCRIPTIONS

THRADJ

VCC

1

2

3

4

5

6

7

8

9

36VCC

35VCC

34VEE

33VEE

32 SEL0

31 NC

30 SEL1

29VEE

28VCC

27VEE

26VCC

25 CF2

PIN 1

INDICATOR

VEE

VREF

NIN

SLICEP

SLICEN

VEE

LOL 10

XO1 11

XO2 12

ADN2807

TOPVIEW

Figure 2. Pin Configuration

Table 3. Pin Function Descriptions

Pin No.

1

2, 26, 28, Pad

Mnemonic

THRADJ

VCC

Type¹Description

AI

P

LOS Threshold Setting Resistor.

Analog Supply.

3, 9, 16, 19,

VEE

P

Ground.

22, 27, 29, 33,

34, 42, 43, 46

4

5

VREF

AO

AI

Internal VREF Voltage. Decouple to GND with a 0.1 µF capacitor.

Differential Data Input.

6

NIN

AI

Differential Data Input.

7

8

SLICEP

SLICEN

LOL

XO1

XO2

REFCLKN

REFCLKP

REFSEL

TDINP

TDINN

VCC

AI

DO

AO

DI

AI

P

AO

DI

AO

DI

Differential Slice Level Adjust Input.

Loss-of-Lock Indicator. LVTTL active high.

Crystal Oscillator.

Differential REFCLK Input. LVTTL, LVCMOS, LVPECL, LVDS (LVPECL, LVDS only at 155.52 MHz).

Reference Source Select. 0 = on-chip oscillator with external crystal. 1 = external clock source, LVTTL.

Differential Test Data Input. CML.

Digital Supply.

10

11

12

13

14

15

17

18

20, 47

21

23

24

25

30

31

32

35, 36

37

38

39

40

41

44

45

48

CF1

Frequency Loop Capacitor.

REFSEL1

REFSEL0

CF2

SEL1

NC

Reference Frequency Select (See Table 6) LVTTL.

Frequency Loop Capacitor.

Data Rate Select (See Table 5) LVTTL.

No Connect.

SEL0

VCC

DI

P

Data Rate Select (See Table 5) LVTTL.

Output Driver Supply.

DATAOUTN

DATAOUTP

SQUELCH

CLKOUTN

CLKOUTP

BYPASS

SDOUT

LOOPEN

DO

DI

DO

DI

Differential Retimed Data Output. CML.

Disable Clock and Data Outputs. Active high. LVTTL.

Differential Recovered Clock Output. CML.

Bypass CDR Mode. Active high. LVTTL.

Loss-of-Signal Detect Output. Active high. LVTTL.

Enable Test Data Inputs. Active high. LVTTL.

DO

DI

¹Type: P = Power, AI = Analog Input, AO = Analog Output, DI = Digital Input, DO = Digital Output

Rev. A | Page 6 of 20

ADN2807

CLKOUTP

T

H

S

DATAOUTP/N

Figure 3. Output Timing

18

16

14

12

10

8

THRADJ RESISTOR VS. LOSTRIP POINT

6

4

2

0

10

20

30

40

50

60

70

80

90

100

RESISTANCE (kΩ)

Figure 4. LOS Comparator Trip Point Programming

10

9

8

7

6

5

4

3

2

1

0

18

16

14

12

10

8

6

4

2

0

1

2

3

4

5

6

7

8

9

10

0

1

2

3

4

5

6

7

8

9

10

HYSTERESIS (dB)

Figure 5. LOS Hysteresis OC-3, −40°C, 3.6 V,

2²³–1 PRBS Input Pattern, R_TH= 90 kΩ

Figure 6. LOS Hysteresis OC-12, −40°C, 3.6 V,

2²³–1 PRBS Input Pattern, R_TH= 90 kΩ

OUTP

V

CML

SE

OUTN

OUTP–OUTN

V

SE

V

DIFF

0V

Figure 7. Single-Ended vs. Differential Output Specifications

Rev. A | Page 7 of 20

ADN2807

DEFINITION OF TERMS

MAXIMUM, MINIMUM, AND TYPICAL

SPECIFICATIONS

SINGLE-ENDED VS. DIFFERENTIAL

AC coupling is typically used to drive the inputs to the

quantizer. The inputs are internally dc-biased to a common-

mode potential of ~0.6 V. Driving the ADN2807 single-ended

and observing the quantizer input with an oscilloscope probe at

the point indicated in Figure 9 shows a binary signal with

average value equal to the common-mode potential and

instantaneous values both above and below the average value. It

is convenient to measure the peak-to-peak amplitude of this

signal and call the minimum required value the quantizer

sensitivity. Referring to Figure 8, since both positive and

negative offsets need to be accommodated, the sensitivity is

twice the overdrive.

Specifications for every parameter are derived from statistical

analyses of data taken on multiple devices from multiple wafer

lots. Typical specifications are the mean of the distribution of

the data for that parameter. If a parameter has a maximum (or a

minimum) value, that value is calculated by adding to (or

subtracting from) the mean six times the standard deviation of

the distribution. This procedure is intended to tolerate pro-

duction variations. If the mean shifts by 1.5 standard deviations,

the remaining 4.5 standard deviations still provide a failure rate

of only 3.4 parts per million. For all tested parameters, the test

limits are guardbanded to account for tester variation, and

therefore guarantee that no device is shipped outside of data

sheet specifications.

10mV p-p

VREF

INPUT SENSITIVITY AND INPUT OVERDRIVE

SCOPE

PROBE

ADN2807

Sensitivity and overdrive specifications for the quantizer involve

offset voltage, gain, and noise. The relationship between the

logic output of the quantizer and the analog voltage input is

shown in Figure 8. For sufficiently large positive input voltage,

the output is always Logic 1; similarly for negative inputs, the

output is always Logic 0. However, the transitions between

output Logic Levels 1 and 0 are not at precisely defined input

voltage levels, but occur over a range of input voltages. Within

this zone of confusion, the output may be either 1 or 0, or it may

even fail to attain a valid logic state. The width of this zone is

determined by the input voltage noise of the quantizer. The

center of the zone of confusion is the quantizer input offset

voltage. Input overdrive is the magnitude of signal required to

guarantee a correct logic level with a 1 × 10^–10confidence level.

+

QUANTIZER

50Ω 50Ω

VREF

Figure 9. Single-Ended Sensitivity Measurement

5mV p-p

VREF

OUTPUT

SCOPE

PROBE

ADN2807

NOISE

1

+

QUANTIZER

NIN

0

50Ω 50Ω

VREF

INPUT (V p-p)

OFFSET

OVERDRIVE

SENSITIVITY

(2× OVERDRIVE)

Figure 10. Differential Sensitivity Measurement

Figure 8. Input Sensitivity and Input Overdrive

Driving the ADN2807 differentially (Figure 10), sensitivity

seems to improve by observing the quantizer input with an

oscilloscope probe. This is an illusion caused by the use of a

single-ended probe. A 5 mV p-p signal appears to drive the

ADN2807 quantizer. However, the single-ended probe measures

only half the signal. The true quantizer input signal is twice this

value since the other quantizer input is complementary to the

signal being observed.

Rev. A | Page 8 of 20

ADN2807

LOS RESPONSE TIME

0.1

The LOS response time is the delay between the removal of the

input signal and indication of loss of signal (LOS) at SDOUT.

The ADN2807’s response time is 300 ns typ when the inputs are

dc-coupled. In practice, the time constant of ac coupling at the

quantizer input determines the LOS response time.

SLOPE = –20dB/DECADE

ACCEPTABLE

RANGE

JITTER SPECIFICATIONS

The ADN2807 CDR is designed to achieve the best bit-error-

rate (BER) performance, and has exceeded the jitter transfer,

generation, and tolerance specifications proposed for

SONET/SDH equipment defined in the Telcordia Technologies

specification. Jitter is the dynamic displacement of digital signal

edges from their long-term average positions measured in UI

(unit intervals), where 1 UI = 1 bit period. Jitter on the input

data can cause dynamic phase errors on the recovered clock

sampling edge. Jitter on the recovered clock causes jitter on the

retimed data. The following sections briefly summarize the

specifications of the jitter generation, transfer, and tolerance in

accordance with the Telcordia document (GR-253-CORE, Issue

3, September 2000) for the optical interface at the equipment

level, and the ADN2807 performance with respect to those

specifications.

f_C

JITTER FREQUENCY (kHz)

Figure 11. Jitter Transfer Curve

Jitter Tolerance

The jitter tolerance is defined as the peak-to-peak amplitude of

the sinusoidal jitter applied on the input signal that causes a

1 dB power penalty. This is a stress test intended to ensure that

no additional penalty is incurred under the operating

conditions (Figure 12).

15

SLOPE = –20dB/DECADE

Jitter Generation

The jitter generation specification limits the amount of jitter

that can be generated by the device with no jitter and wander

applied at the input.

1.5

Jitter Transfer

0.15

The jitter transfer function is the ratio of the jitter on the output

signal to the jitter applied on the input signal versus the

frequency. This parameter measures the limited amount of jitter

on an input signal that can be transferred to the output signal

(Figure 11).

f

0

f

1

f

2

f

3

f4

JITTER FREQUENCY (Hz)

Figure 12. SONET Jitter Tolerance Mask

Table 4. Jitter Transfer and Tolerance: SONET Specifications vs. ADN2807

Jitter Transfer

Jitter Tolerance

SONET

ADN2807 Implementation

Mask Corner

Frequency (kHz)

SONET Spec ADN2807 Implementation

Rate

OC-12 500 kHz

OC-3 130 kHz

Spec (f_C) (kHz)

Margin

ADN2807 (UI p-p)

(UI p-p)

Margin²

6.67

140

48

3.6

2.7

250 kHz

65 kHz

4.8 MHz

600 kHz

0.15

1.0

6.67

²Jitter tolerance measurements are limited by test equipment capabilities.

Rev. A | Page 9 of 20

ADN2807

THEORY OF OPERATION

psh

e(s)

The ADN2807 is a delay-locked and phase-locked loop circuit

for clock recovery and data retiming from an NRZ encoded

data stream. The phase of the input data signal is tracked by two

separate feedback loops that share a common control voltage. A

high speed delay-locked loop path uses a voltage controlled

phase shifter to track the high frequency components of the

input jitter. A separate phase control loop, comprised of the

VCO, tracks the low frequency components of the input jitter.

The initial frequency of the VCO is set by a third loop, which

compares the VCO frequency with the reference frequency and

sets the coarse tuning voltage. The jitter tracking phase-locked

loop controls the VCO by the fine tuning control. The delay-

and phase-locked loops together track the phase of the input

data signal. For example, when the clock lags input data, the

phase detector drives the VCO to a higher frequency and also

increases the delay through the phase shifter. Both of these

actions serve to reduce the phase error between the clock and

data. The faster clock picks up phase while the delayed data

loses phase. Since the loop filter is an integrator, the static phase

error will be driven to zero.

X(s)

INPUT

DATA

o/s

d/sc

1/n

Z(s)

RECOVERED

CLOCK

JITTERTRANSFER FUNCTION

d = PHASE DETECTOR GAIN

o = VCO GAIN

c = LOOP INTEGRATOR

psh = PHASE SHIFTER GAIN

n = DIVIDE RATIO

Z(s)

X(s)

1

=

cn

do

n psh

2

s

+ s

+1

o

TRACKING ERRORTRANSFER FUNCTION

2

e(s)

X(s)

s

=

d psh

do

cn

2

s

+ s

+

c

Figure 13. PLL/DLL Architecture

The error transfer, e(s)/X(s), has the same high-pass form as an

ordinary phase-locked loop. This transfer function is free to be

optimized to give excellent wideband jitter accommodation

since the jitter transfer function, Z(s)/X(s), provides the narrow-

band jitter filtering. See Table 4 for error transfer bandwidths

and jitter transfer bandwidths at the various data rates. The

delay-locked and phase-locked loops contribute to overall jitter

accommodation. At low frequencies of input jitter on the data

signal, the integrator in the loop filter provides high gain to

track large jitter amplitudes with small phase error. In this case,

the VCO is frequency modulated, and jitter is tracked as in an

ordinary phase-locked loop. The amount of low frequency jitter

that can be tracked is a function of the VCO tuning range. A

wider tuning range gives larger accommodation of low

frequency jitter. The internal loop control voltage remains small

for small phase errors, so the phase shifter remains close to the

center of its range and thus contributes little to the low

frequency jitter accommodation.

Another view of the circuit is that the phase shifter implements

the zero required for the frequency compensation of a second-

order phase-locked loop. This zero is placed in the feedback

path and, therefore, does not appear in the closed-loop transfer

function. Jitter peaking in a conventional second-order phase-

locked loop is caused by the presence of this zero in the closed-

loop transfer function. Since this circuit has no zero in the

closed-loop transfer, jitter peaking is minimized.

The delay- and phase-locked loops together simultaneously

provide wideband jitter accommodation and narrow-band jitter

filtering. The linearized block diagram in Figure 13 shows that

the jitter transfer function, Z(s)/X(s), is a second-order low-pass

providing excellent filtering. Note that the jitter transfer has no

zero, unlike an ordinary second-order phase-locked loop. This

means the main PLL loop has low jitter peaking (Figure 14),

which makes this circuit ideal for signal regenerator

applications where jitter peaking in a cascade of regenerators

can contribute to hazardous jitter accumulation.

Rev. A | Page 10 of 20

ADN2807

the eye opening of the input data, the static phase error, and the

residual loop jitter generation. The jitter accommodation is

roughly 0.5 UI in this region. The corner frequency between the

declining slope and the flat region is the closed loop bandwidth

of the delay-locked loop, which is roughly 5 MHz for OC-12

data rates and 600 kHz for OC-3 data rates.

At medium jitter frequencies, the gain and tuning range of the

VCO are not large enough to track the input jitter. In this case,

the VCO control voltage becomes large and saturates, and the

VCO frequency dwells at one or the other extreme of its tuning

range. The size of the VCO tuning range, therefore, has only a

small affect on the jitter accommodation. The delay-locked loop

control voltage is now larger; therefore, the phase shifter takes

on the burden of tracking the input jitter. The phase shifter

range, in UI, can be seen as a broad plateau on the jitter

tolerance curve. The phase shifter has a minimum range of 2 UI

at all data rates.

JITTER PEAKING

IN ORDINARY PLL

JITTER

GAIN

ADN2807

(dB)

The gain of the loop integrator is small for high jitter

Z(s)

X(s)

frequencies, so larger phase differences are needed to make the

loop control voltage big enough to tune the range of the phase

shifter. Large phase errors at high jitter frequencies cannot be

tolerated. In this region, the gain of the integrator determines

the jitter accommodation. Since the gain of the loop integrator

declines linearly with frequency, jitter accommodation is lower

with higher jitter frequency. At the highest frequencies, the loop

gain is very small, and little tuning of the phase shifter can be

expected. In this case, jitter accommodation is determined by

f

(kHz)

d psh

c

o

n psh

Figure 14. Jitter Response vs. Conventional PLL

Rev. A | Page 11 of 20

ADN2807

FUNCTIONAL DESCRIPTION

Note that it is not expected to use both LOS and slice adjust at

the same time. Systems with optical amplifiers need the slice

adjust to evade ASE. However, a loss-of-signal in an optical link

that uses optical amplifiers causes the optical amplifier output

to be full-scale noise. Under this condition, the LOS would not

detect the failure. In this case, the loss-of-lock signal indicates

the failure because the CDR circuitry is unable to lock onto a

signal that is full-scale noise.

MULTIRATE CLOCK AND DATA RECOVERY

The ADN2807 recovers clock and data from serial bit streams at

OC-3, OC-12 data rates as well as the 15/14 FEC rates. The

output of the 2.5 GHz VCO is divided down in order to support

the lower data rates. The data rate is selected by the SEL[2..0]

inputs (Table 5).

Table 5. Data Rate Selection

SEL[1..0]

Rate

Frequency (MHz)

622.08

155.52

666.51

166.63

REFERENCE CLOCK

00

01

10

11

OC-12

OC-3

OC-12 FEC

OC-3 FEC

There are three options for providing the reference frequency to

the ADN2807: differential clock, single-ended clock, or crystal

oscillator. See Figure 15 to Figure 17 for example configurations.

ADN2807

LIMITING AMPLIFIER

REFCLKP

The limiting amplifier has differential inputs (PIN/NIN) that

are internally terminated with 50 Ω to an on-chip voltage

reference (VREF = 0.6 V typically). These inputs are normally

ac-coupled, although dc-coupling is possible as long as the input

common-mode voltage remains above 0.4 V (Figure 24 to

Figure 26 in the Applications Information section). Input offset

is factory trimmed to achieve better than 4 mV typical

sensitivity with minimal drift. The limiting amplifier can be

driven differentially or single-ended.

BUFFER

REFCLKN

100kΩ 100kΩ

VCC/2

XO1

VCC

CRYSTAL

XO2

OSCILLATOR

VCC

REFSEL

SLICE ADJUST

The quantizer slicing level can be offset by 100 mV to mitigate

the effect of ASE (amplified spontaneous emission) noise by

applying a differential voltage input of 0.8 V to SLICEP/N

inputs. If no adjustment of the slice level is needed, SLICEP/N

should be tied to VCC.

Figure 15. Differential REFCLK Configuration

ADN2807

VCC

REFCLKP

CLK

OSC

OUT

LOSS-OF-SIGNAL (LOS) DETECTOR

BUFFER

REFCLKN

NC

The receiver front end level signal detect circuit indicates when

the input signal level has fallen below a user adjustable

threshold. The threshold is set with a single external resistor

from THRADJ (Pin 1) to GND. The LOS comparator trip point

versus the resistor value is illustrated in Figure 4 (this is only

valid for SLICEP = SLICEN = VCC). If the input level to the

ADN2807 drops below the programmed LOS threshold,

SDOUT (Pin 45) will indicate the loss-of-signal condition with

a Logic 1. The LOS response time is ~300 ns by design but will

be dominated by the RC time constant in ac-coupled

applications. If the LOS detector is used, the quantizer slice

adjust pins must both be tied to VCC. This is to avoid

interaction with the LOS threshold level.

100kΩ 100kΩ

VCC/2

XO1

VCC

CRYSTAL

OSCILLATOR

XO2

VCC

REFSEL

Figure 16. Single-Ended REFCLK Configuration

Rev. A | Page 12 of 20

ADN2807

Table 7. Required Crystal Specifications

ADN2807

Parameter

Value

VCC

Mode

Series Resonant

19.44 MHz 100 ppm

100 ppm

REFCLKP

Frequency/Overall Stability

Frequency Accuracy

Temperature Stability

Aging

BUFFER

NC

REFCLKN

100kΩ 100kΩ

VCC/2

ESR

50 Ω max

XO1

XO2

REFSEL must be tied to VCC when the REFCLKN/P inputs are

active or to VEE when the oscillator is used. No connection

between the XO pin and REFCLK input is necessary (Figure 15

to Figure 17). Note that the crystal should operate in series

resonant mode, which renders it insensitive to external

parasitics. No trimming capacitors are required.

CRYSTAL

OSCILLATOR

19.44MHz

REFSEL

Figure 17. Crystal Oscillator Configuration

LOCK DETECTOR OPERATION

The ADN2807 can accept any of the following reference clock

frequencies: 19.44 MHz, 38.88 MHz, and 77.76 MHz at LVTTL/

LVCMOS/LVPECL/LVDS levels, or 155.52 MHz at LVPECL/

LVDS levels via the REFCLKN/P inputs, independent of data

rate. The input buffer accepts any differential signal with a

peak-to-peak differential amplitude of greater than 100 mV

(e.g., LVPECL or LVDS) or a standard single-ended low voltage

TTL input, providing maximum system flexibility. The

appropriate division ratio can be selected using the REFSEL0/1

pins according to Table 6. Phase noise and duty cycle of the

reference clock are not critical, and 100 ppm accuracy is

sufficient.

The lock detector monitors the frequency difference between

the VCO and the reference clock and deasserts the loss-of-lock

signal when the VCO is within 500 ppm of center frequency.

This enables the phase loop, which then maintains phase lock,

unless the frequency error exceeds 0.1%. Should this occur, the

loss-of-lock signal is reasserted and control returns to the

frequency loop, which will reacquire and maintain a stable clock

signal at the output. The frequency loop requires a single

external capacitor between CF1 and CF2. The capacitor

specification is given in Table 8.

Table 8. Recommended C_FCapacitor Specification

An on-chip oscillator to be used with an external crystal is also

provided as an alternative to using the REFCLKN/P inputs.

Details of the recommended crystal are given in Table 7.

Parameter

Temperature Range

Capacitance

Leakage

Value

–40°C to +85°C

>3.0 µF

<80 nA

Rating

>6.3 V

Table 6. Reference Frequency Selection

Applied Reference

REFSEL REFSEL[1..0] Frequency (MHz)

1

0

00

01

10

11

XX

19.44

38.88

77.76

155.52

REFCLKP/N Inactive. Use 19.44 MHz

XTAL on Pins XO1, XO2 (Pull REFCLKP

to VCC)

LOL

1

1000

500

0

500

1000

f

ERROR

VCO

(ppm)

Figure 18. Transfer Function of LOL

Rev. A | Page 13 of 20

ADN2807

+

NIN

0

1

QUANTIZER

CDR

RETIMED

50Ω 50Ω

FROM

QUANTIZER

OUTPUT

DATA

CLK

VREF

1

0

50Ω 50Ω

VCC

TDINP/N

LOOPEN BYPASS DATAOUTP/N

CLKOUTP/N SQUELCH

Figure 19. Test Modes

The loopback mode can be invoked by driving the LOOPEN

pin to a TTL high state, which facilitates system diagnostic

testing. This will connect the test inputs (TDINP/N) to the

clock and data recovery circuit (per Figure 19). The test inputs

have internal 50 Ω terminations and can be left floating when

not in use. TDINP/N are CML inputs and can be dc-coupled

only when being driven by CML outputs. The TDINP/N inputs

must be ac-coupled if driven by anything other than CML

outputs. Bypass and loop-back modes are mutually exclusive;

only one of these modes can be used at any given time. The

ADN2807 is put into an indeterminate state if both BYPASS

and LOOPEN pins are set to Logic 1 at the same time.

SQUELCH MODE

When the squelch input is driven to a TTL high state, both the

clock and data outputs are set to the zero state to suppress

downstream processing. If desired, this pin can be directly

driven by the LOS (loss-of-signal) detector output (SDOUT). If

the squelch function is not required, the pin should be tied to

VEE.

TEST MODES—BYPASS AND LOOP-BACK

When the bypass input is driven to a TTL high state, the

quantizer output is connected directly to the buffers driving the

data out pins, thus bypassing the clock recovery circuit

(Figure 19). This feature can help the system to deal with

nonstandard bit rates.

Rev. A | Page 14 of 20

ADN2807

APPLICATION INFORMATION

PCB DESIGN GUIDELINES

matched in length and that the CLKOUTP/N and

DATAOUTP/N traces are matched in length. All high speed

CML outputs, CLKOUTP/N and DATAOUTP/N, also require

100 Ω back termination chip resistors connected between the

output pin and VCC. These resistors should be placed as close

as possible to the output pins. These 100 Ω resistors are in

parallel with on-chip 100 Ω termination resistors to create a

50 Ω back termination (Figure 21).

Proper RF PCB design techniques must be used for optimal

performance.

Power Supply Connections and Ground Planes

Use of one low impedance ground plane to both analog and

digital grounds is recommended. The VEE pins should be

soldered directly to the ground plane to reduce series

inductance. If the ground plane is an internal plane and

connections to the ground plane are made through vias,

multiple vias may be used in parallel to reduce the series

inductance, especially on Pins 33 and 34, which are the ground

returns for the output buffers.

The high speed inputs, PIN and NIN, are internally terminated

with 50 Ω to an internal reference voltage (Figure 22). A 0.1 µF

capacitor is recommended between VREF (Pin 4) and GND to

provide an ac ground for the inputs.

As with any high speed mixed-signal design, care should be

taken to keep all high speed digital traces away from sensitive

analog nodes.

Use of a 10 µF electrolytic capacitor between VCC and GND is

recommended at the location where the 3.3 V supply enters the

PCB. Use of 0.1 µF and 1 nF ceramic chip capacitors should be

placed between IC power supply VCC and GND as close as

possible to the ADN2807’s VCC pins. Again, if connections to

the supply and ground are made through vias, the use of

multiple vias in parallel will help to reduce series inductance,

especially on Pins 35 and 36, which supply power to the high

speed CLKOUTP/N and DATAOUTP/N output buffers. Refer

to the schematic in Figure 20 for recommended connections.

Soldering Guidelines for Chip Scale Package

The leads on the 48-lead LFCSP are rectangular. The printed

circuit board pad for these should be 0.1 mm longer than the

package lead length and 0.05 mm wider than the package lead

width. The land should be centered on the pad. This ensures

that solder joint size is maximized. The bottom of the LFCSP

has a central exposed pad. The pad on the printed circuit board

should be at least as large as this exposed pad. The user must

connect the exposed pad to analog VCC. If vias are used, they

should be incorporated into the pad at 1.2 mm pitch grid. The

via diameter should be between 0.3 mm and 0.33 mm, and the

via barrel should be plated with 1 oz. copper to plug the via.

Transmission Lines

Use of 50 Ω transmission lines are required for all high

frequency input and output signals to minimize reflections,

including PIN, NIN, CLKOUTP, CLKOUTN, DATAOUTP, and

DATAOUTN (also REFCLKP/N for a 155.52 MHz REFCLK). It

is also recommended that the PIN/NIN input traces are

Rev. A | Page 15 of 20

ADN2807

VCC

50Ω

TRANSMISSION

LINES

4 × 100Ω

CLKOUTP

CLKOUTN

DATAOUTP

DATAOUTN

VCC

µC

10µF

0.1µF

1nF

48 47 46 45 44 43 42 41 40 39 38 37

R

TH

THRADJ

VCC

36

1

VCC

VEE

SEL0

NC

2

35

34

33

32

31

30

29

28

27

26

25

VCC

1nF

0.1µF

1nF

VEE

3

0.1µF

VREF

4

50Ω

EXPOSED PAD

TIED OFFTO

VCC PLANE

WITH VIAS

µC

NC

µC

5

TIA

NIN

6

SLICEP

SLICEN

VEE

SEL1

VEE

VCC

VEE

VCC

CF2

C

50Ω

IN

7

VCC

8

9

0.1µF

LOL

1nF

0.1µF

1nF

10

11

12

µC

19.44MHz

XO1

VCC

ADN2807

XO2

20 21 22 23 24

13 14 15 16 17 18 19

4.7µF

(SEETABLE8 FOR SPECS)

VCC

0.1µF

1nF

Figure 20. Typical Application Circuit

VCC

ADN2807

VCC

C

IN

50Ω

NIN

V

TERM

TIA

100Ω 100Ω

IN

50Ω

0.1µF

50Ω

VREF

50Ω

0.1µF

ADN2807

V

TERM

Figure 22. AC-Coupled Input Configuration

Figure 21. AC-Coupled Output Configuration

Rev. A | Page 16 of 20

ADN2807

CHOOSING AC COUPLING CAPACITORS

LOL TOGGLING DURING LOSS OF INPUT DATA

The ac coupling capacitors at the input (PIN, NIN) and output

(DATAOUTP, DATAOUTN) of the ADN2807 must be chosen

so that the device works properly at both OC-3 and OC-12 data

rates. When choosing the capacitors, the time constant formed

with the two 50 Ω resistors in the signal path must be

considered. When a large number of consecutive identical digits

(CIDs) are applied, the capacitor voltage can drop due to

baseline wander (Figure 23), causing pattern dependent jitter

(PDJ). For the ADN2807 to work robustly at both OC-3 and

OC-12, a minimum capacitor of 0.1 µF to PIN/NIN and 0.1 µF

on DATAOUTP/DATAOUTN should be used. This is based on

the assumption that 1000 CIDs must be tolerated, and that the

PDJ should be limited to 0.01 UI p-p.

If the input data stream is lost due to a break in the optical link

(or for any reason), the clock output from the ADN2807 stays

within 1000 ppm of the VCO center frequency as long as there

is a valid reference clock. The LOL pin will toggle at a rate of

several kHz. This is because the LOL pin will toggle between a

Logic 1 and Logic 0 while the frequency loop and phase loop

swap control of the VCO. The chain of events is as follows:

•

The ADN2807 is locked to the input data stream; LOL = 0.

The input data stream is lost due to a break in the link. The

VCO frequency drifts until the frequency error is greater

than 1000 ppm. LOL is asserted to a Logic 1 as control of

the VCO is passed back to the frequency loop.

DC-COUPLED APPLICATION

•

The frequency loop pulls the VCO to within 500 ppm of its

center frequency. Control of the VCO is passed back to the

phase loop and LOL is deasserted to Logic 0.

The inputs to the ADN2807 can also be dc-coupled. This may

be necessary in burst mode applications where there are long

periods of CIDs, and where baseline wander cannot be

tolerated. If the inputs to the ADN2807 are dc-coupled, care

must be taken not to violate the input range and common-mode

level requirements of the ADN2807 (Figure 24 to Figure 26). If

dc coupling is required and the output levels of the TIA do not

adhere to the levels shown in Figure 25 and Figure 26, there

must be level shifting and/or an attenuator between the TIA

outputs and the ADN2807 inputs.

•

The phase loop tries to acquire, but there is no input data

present so the VCO frequency drifts.

The VCO frequency drifts until the frequency error is

greater than 1000 ppm. LOL is asserted to a Logic 1 as

control of the VCO is passed back to the frequency loop.

This process is repeated until a valid input data stream is

re-established.

ADN2807

C

OUT

V1

IN

V2

NIN

+

DATAOUTP

DATAOUTN

50Ω

V

LIMAMP

CDR

REF

TIA

C

OUT

V1b

V2b

50Ω

IN

2

3

4

1

V1

V1b

V2

V

REF

V2b

VTH

V

DIFF

V

= V2–V2b

DIFF

VTH = ADN2807 QUANTIZERTHRESHOLD

NOTES

1. DURING DATA PATTERNS WITH HIGH TRANSITION DENSITY, DIFFERENTIAL DC VOLTAGE AT V1 AND V2 IS 0.

2. WHENTHE OUTPUT OFTHE TIA GOESTO CID, V1 AND V1b ARE DRIVENTO DIFFERENT DC LEVELS. V2 AND V2b

DISCHARGETOTHEV LEVEL,WHICH EFFECTIVELY INTRODUCES A DIFFERENTIAL DC OFFSET ACROSSTHE AC COUPLING CAPACITORS.

REF

3. WHENTHE BURST OF DATA STARTS AGAIN,THE DIFFERENTIAL DC OFFSET ACROSSTHE AC COUPLING CAPACITORS IS APPLIEDTOTHE INPUT LEVELS,

CAUSING A DC SHIFT INTHE DIFFERENTIAL INPUT. THIS SHIFT IS LARGE ENOUGH SUCHTHAT ONE OFTHE STATES, EITHER HIGH OR LOW DEPENDING ON

THE LEVELS OF V1 AND V1bWHENTHE TIAWENTTO CID, IS CANCELLED OUT. THE QUANTIZERWILL NOT RECOGNIZETHIS AS AVALID STATE.

4. THE DC OFFSET SLOWLY DISCHARGES UNTILTHE DIFFERENTIAL INPUTVOLTAGE EXCEEDSTHE SENSITIVITY OFTHE ADN2807.THE QUANTIZER WILL BE

ABLETO RECOGNIZE BOTH HIGH AND LOW STATES ATTHIS POINT.

Figure 23. Example of Baseline Wander

Rev. A | Page 17 of 20

ADN2807

INPUT (V)

VCC

ADN2807

V p-p = PIN – NIN = 2 × V = 2.4V MAX

SE

50Ω

NIN

TIA

V

= 1.2V MAX

SE

V

= 0.6V

CM

(DC-COUPLED)

50Ω

NIN

VREF

0.1µ F

Figure 26. Maximum Allowed DC-Coupled Input Levels

Figure 24. ADN2807 with DC-Coupled Inputs

INPUT (V)

V p-p = PIN – NIN = 2 × V = 10mV AT SENSITIVITY

SE

NIN

V

= 5mV MIN

SE

V

= 0.4V MIN

CM

(DC-COUPLED)

Figure 25. Minimum Allowed DC-Coupled Input Levels

Rev. A | Page 18 of 20

ADN2807

OUTLINE DIMENSIONS

0.30

0.23

0.18

7.00

BSC SQ

0.60 MAX

PIN 1

INDICATOR

37

36

48

1

PIN 1

INDICATOR

5.25

5.10 SQ

4.95

6.75

BSC SQ

TOP

VIEW

BOTTOM

VIEW

0.50

0.40

0.30

25

24

12

13

0.25 MIN

5.50

REF

0.80 MAX

0.65 TYP

1.00

0.85

0.80

ꢀ

12° MAX

0.05 MAX

0.02 NOM

COPLANARITY

0.08

0.50 BSC

0.20 REF

SEATING

PLANE

COMPLIANT TO JEDEC STANDARDS MO-220-VKKD-2

Figure 27. 48-Lead Lead Frame Chip Scale Package [LFCSP]

7 mm × 7 mm Body (CP-48)

Dimensions shown in millimeters

ORDERING GUIDE

Model

ADN2807ACP

ADN2807ACP-RL

Temperature Range

–40°C to +85°C

Package Description

48-Lead LFCSP

Package Option

CP-48

Rev. A | Page 19 of 20

ADN2807

NOTES

©

registered trademarks are the property of their respective owners.

D03877–0–5/04(A)

Rev. A | Page 20 of 20


型号：	ADN2807ACP
厂家：	ADI
描述：	155/622 Mb/s Clock and Data Recovery IC with Integrated Limiting Amp 155/622 Mb / s的时钟和数据恢复IC，集成限幅放大器放大器时钟
文件：	总20页 (文件大小：354K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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